DE2554362A1 - DEMAGNETIZING CIRCUIT ARRANGEMENT - Google Patents

Description

PHN.7853. YIJN / EVH. ϊ>. J--:. Λ;, .- ·: ■. y ...: irr November 19, 1975.

255A362

¹¹ Ent magnet! safety circuit arrangement "

The invention relates to a demagnetization circuit arrangement, containing the series connection of a degaussing coil with a thermistor having a positive temperature coefficient, means for connecting the series circuit to the terminals of an AC voltage source and a resistance element for heating the thermistor.

Such a circuit arrangement, for example for demagnetizing the protective hood and the shadow mask of shadow mask color television tubes can be used is known from German patent specification 1 282 679. · So that the

6 0 9 8 2 6/0898 ORIGINAL INSPECTED

PHN.7853. 11/19/75

magnetizing coil at the end of the demagnetizing process flowing sti-om is reduced, the. an undesirable remanent magnetism in the to be demagnetized cause ferromagnetic parts the thermistor is brought to a higher temperature than that by means of the resistance element which would be caused by the end current alone. This further increases the resistance of the thermistor.

In the known circuit arrangement can

In practice, a wire-wound resistance element is used as the resistance element Resistor with high permissible power should be used, which is in the immediate vicinity of the thermistor is arranged. The disadvantage of this measure, however, is because of the temperature of the wire-wound Resistance is less manageable that deχ Difference between the maximum allowable temperature of the thermistor and the ambient temperature does not matter Security can be controlled. This creates the risk of harmful overheating of the thermistor. This circuit arrangement is therefore no longer used.

The invention now aims to avoid the disadvantage of the known circuit arrangement and for this purpose, according to the invention, is characterized in that the resistance element has a second thermistor is a positive temperature coefficient that corresponds to the

609826/0898

PIHf. 7353. 11/19/75. - 3 -

Clamps of the AC voltage source can be connected and is thermally coupled to the first thermistor.

By transferring heat from the second to the first thermistor, this actually achieves one higher temperature »However, a state of equilibrium arises, after which the temperature is no longer significant can increase, so that the circuit arrangement according to the invention works reliably. Degaussing circuits with two thermistors thermally coupled to one another are known per se. The publication in "Philips Product Information 43": "Magnetic Shielding and Automatic Degaussing of Shadow Mask Tubes "from January 27, 1972 »describes such a circuit arrangement, in which, however, the second thermistor is not connected to the terminals of the AC voltage source but is in series with the first thermistor and with which a very expensive parallel resistance is higher permissible power is used. Such an expensive resistor can be made possible by the measure according to the invention fall away. '·

The invention also relates to an assembled thermistor element for use in degaussing circuitry having a first and a second thermistor with a positive one Temperature coefficients that are thermally related to each other

609826/0898

PHN.7853. 11/19/75. _ 4 -

are coupled. This element is characterized by that the resistance value of the second thermistor, measured at a temperature higher than the highest Curie temperature, lower than the resistance value of the first thermistor measured at the same temperature, is.

An embodiment of the invention is shown in the drawing and is described below described in more detail »Show it

1 shows the circuit arrangement according to the invention,

Fig. 2 and 3 characteristic curves for explaining the invention,

Fig. H shows a thermistor element according to the invention.

In Fig. 1 is a Entmagnetisieruiigs- reel 1, for example, an unillustrated FarbfemsehbildrShre from the shadow mask type, in series with a thermistor 2 with a positive temperature coefficient, The series circuit formed is applied to terminals 3 and h of an AC voltage source 5 ", for example, to the electrical supply network , can be connected via a power switch 6. Parallel to the series connection of the Eritmagnetisier'ungsspule 1 and the thermistor 2 is a. second thermistor 7 »

809826/0898

PHN.7853 *

11/19/75. - 5 -

also has a positive temperature coefficient «The thermistors 2 and 7 are therefore thermally connected to one another coupled by being brought into intimate contact with one another, as in Fig. 1 by an arrow specified.

When cold, the two thermistors 2 and 7 have relatively small resistance values. Immediately after the power switch 6 is switched on, large currents therefore flow through the two parallel ones Branches of the circuit arrangement. The current through the demagnetization coil 1 has an initial amplitude of about 5 A or more. Because the thermistor 7 is parallel to the AC voltage is equal to 5, the current is through the Thermistor 7 independent of the demagnetization current through the thermistor 2 and the demagnetization coil 1 » The two currents heat the thermistors 2 and 7 in a fairly short time, e.g. in about 10s.

In FIG. 2, the resistance value R of the thermistor 2 as a characteristic curve a and of the thermistor 7 as a characteristic curve b as a function of the temperature T are plotted on a logarithmic scale. Above the so-called Curie temperature T, for example at about 75 ^° C., the specific resistance of the material from which the thermistor 2 is made, and therefore also its resistance value, increase very sharply. Self-heating would occur if there was no

609826/0898

-PHN.7853.

11/19/75.

of the thermistor 7, the thermistor 2 reach a temperature T ₁ , for example at about 130 ^° C., with a corresponding resistance value R- of about 25 kOhm, whereby the amplitude of the demagnetizing current is reduced to a value of about 8 mA.

From Fig. 2 it can be seen that the thermistor 7 has been selected in such a way that it has a higher Curie temperature T ·, for example, about 120 ° C, than the thermistor 2 is. This means that the thermistor 7 the Temperature T 'reaches temperature T at a later point in time than the thermistor 2. The thermistor 7 therefore does not warm up as quickly as the thermistor 2. After a certain time after the temperature has been reached T therefore becomes the current through the thermistor 2

so small that the decrease in the factor i im

2 '

Expression i R of the power consumed the increase in the Factor R covered. This power becomes smaller than the power consumed by the thermistor 7. The thermistor 7 therefore gives off heat to the thermistor 2. Since a part of the heat given off by the thermistor 7 nevertheless is discharged into the environment, the temperature of thermistor 2 will be lower than that of thermistor 7 It follows from this that the thermistor 7 only reacts to the demagnetizing current after a certain time Has influence.

60 9 826/0898

PHN.7853. 11/19/75 o

The thermistor 7 reaches a temperature T * which is obtained as a T, whereby the thermistor 2 by heat transfer to a final temperature T in a practical circuit arrangement by about 50 ° C higher, which is higher by about 20 to 3O ⁰ C as T. A state of equilibrium occurs in which the end temperature of the thermistor 7 is somewhat lower than T ^f - and in which the two thermistors 2 and 7 are kept at approximately the stated end temperatures by the end currents. This state is stable because an increase in temperature causes a decrease in the current and counteracts the increase in temperature. This also prevents the temperature from rising to such an extent that areas of the falling characteristic curves a and / or b are reached (see FIG. 2) in which the resistance value falls »The final value Rp of the thermistor 2 is greater than R- . namely it is about 200kΩ, and the final amplitude of the current through the coil 1 is reduced to the desired value, ie to about 1 mA.

In FIG. 3, the current i through the thermistor 2 is plotted as a function of the voltage ν across the thermistor 2. Characteristic curve a applies to a lower ambient temperature than characteristic curve b. Through the Effect of the thermistor 7 increases the ambient temperature of the thermistor 2 and it can be seen from FIG. 3,

609826/0898

PHN. 7853.

11/19/75.

that the current i is actually decreased. One The condition for this is that the thermistor 7 is in its final state power absorbed by its own heating is higher than that of thermistor 2, which means that the final value of the resistance of the thermistor 7 is lower than that of the thermistor 2, as can also be seen from FIG. It is assumed that the power loss in the degaussing coil 1 is in the final state negligibly small compared to that in thermistor 2 is because the ohmic resistance value of the Degaussing coil 1 much smaller than the value R " is, e.g. about 20 ohms, versus about 200 kOhms, so that the final voltage drop across the degaussing coil is negligibly small. .

Compared to the case in which the thermistor is a linear resistor, the result according to the invention Circuit arrangement a substantial energy saving; The final value of the current through the thermistor is so small that its power consumption is many times smaller than that generated by the nearly constant current caused by the linear resistance. Another saving is thereby too obtained by for the thermistor 7 a. Type is chosen that has a higher initial value than the thermistor when cold, i.e. about 1 kOhm versus about

609826/089 8

PHN.7853.

11/19/75. - 9 -

25 to kO ohms. Of the. The initial value of the thermistor 2 is namely determined by the desired size of the initial amplitude of the demagnetizing current and should therefore be small.

Compared to the circuit arrangement described in the above publication, which also contains a linear resistance, there is a cost saving. In addition, the price of the Thermistors 2 and 7 formed item not higher than the corresponding item of the known circuit arrangement .

In Fig. 4 the "duo-PTC" (PTC = positive ■ temperature coefficient) according to the invention. The single part consists of two thermistors 2 and 7 Form of disks made of PTC material, for example barium titanate, between three spring contacts 8, 9 10 clamped and enclosed by a plastic housing 11 are. The contact 9 corresponds in Fig. 1 to the connection point of the two thermistors 2 and 7 »during the contact 8 is the connection shown in FIG of the thermistor 7 and the contact tO the connection point between the thermistor 2 and the degaussing coil 1 is. Because the two thermistors 2 and 7 are full Have to withstand mains voltage, they have almost the same thickness, while the "duo-PTC" the well-known

609826/0898

i ₄ 7853.

.19.11.75. - 10 -

Circuit arrangement from a thick and a thin Thermistor. The cost of sintering the thick thermistors is slightly lower, which makes the higher material costs are almost offset.

A higher Curie temperature for the

Thermistor 7 is obtained in that the PTC material the barium is replaced by lead. Also can on the other hand a lower Curie temperature for the thermistor can be obtained by replacing the barium with strontium is replaced.

The circuit arrangement described can also be used, for example, for demagnetizing tools or for Erasing magnetic tapes are used in tape recording and / or playback devices »

609826/0898

Claims (1)

PHN.7853. 11/19/75 »- • 11 - PATENT CLAIMS ; 1, j demagnetization circuitry, containing the series connection of a degaussing coil with a positive temperature coefficient having thermistor, means for connecting the Series connection to the terminals of an alternating voltage source iind a resistance element for ErwSrraen the Thermistor, characterized in that the resistance element is a second thermistor (7) with a positive temperature coefficient, which is connected to the terminals (3 »^) the AC voltage source can be connected and is thermally coupled to the first thermistor (2). 2 »Circuit arrangement according to claim 1, characterized characterized in that the resistance value of the second thermistor (7) in the equilibrium state during operation is lower than the resistance value (R ₂ ) of the first thermistor (2), 3 · Circuit arrangement according to claim 1, characterized characterized in that the temperature of the second thermistor (7) in the steady state during operation is higher than is the temperature (Tp) of the first thermistor (2). 4 »Circuit arrangement according to claim 1, characterized characterized in that the resistance value of the second. Thermistor (7) when cold is higher than the resistance s value of the first thermistor (2), 609826/0898 PHN.7853. ■ 11/19/75. - 12 - 5 · Circuit arrangement according to one of the preceding Claims, characterized in that the Curie temperature (Τ ¹ ) of the second thermistor (7) is higher than the Curie temperature (τ) of the first thermistor (2). 6 · 'Thermisto ¹ 3? ^{e lemen} 'fc »consisting of two thermally coupled thermistors with positive temperature coefficients, characterized in that the resistance value of one (second) thermistor (7) measured at a higher temperature than the highest Curie temperature (Τ ¹ ) is lower than the resistance value of the other (first) thermistor (2), measured at the same temperature « 7 »thermistor element according to claim 6, characterized in that the resistance value of the second thermistor (7) »i ^m cold state higher than the resistance value of the first thermistor (2) is" 8 "thermistor according to any one of claims 6 and 7f characterized in that the Curie temperature (T » _o ) of the second thermistor (7) is higher than that (T _q ) of the first thermistor (2)» "9. thermistor element according to claim 8, characterized characterized in that the molecule of the material from which the second thermistor (7) is made contains more lead as the molecule of the material from which the first thermistor (2) is made. 609826/0898 PHN. 7853. 11/19/75. - 13 - 10, thermistor element according to claim 8, dadtxrch indicated that the molecule of the material from which the first thermistor (2) is made contains more strontium as the molecule of the material from which the second thermistor (7) is made » 60 98 2 6/08 98 Lee r s e i t